Complementarity of thermoregulatory rhythms in Micropterus salmoides and M. dolomieui

Largemouth (Micropterus salmoide) and smallmouth (M. dolomieui) blackbasses tested in an electronic shuttlebox exhibited behavioral thermoregulatory rhythms which were temporally complementary. With a LD 12 : 12 photoperiod, M. dolomieui exhibited a preferred-temperature peak of 30.1°C during the latter portion of the photophase, when M. salmoides reached a minimum of 27.1°C. M. dolomieui exhibited a minimum of 26.6°C during the latter portion of scotophase, while M. salmoides remained at a significantly higher plateau of about 29°C, with a peak of 29.5°C at the midpoint of scotophase. The phase relations of the thermoregulatory rhythms relative to photoperiod suggest that they are endogenously timed circadian rhythms entrained by photoperiod. The thermotemporal complementarity of these rhythms suggests an aspect of niche segregation between these largely sympatric congeneric species.     

Behavioral thermoregulation by Ammocoete larvae of the sea lamprey (Petromyzon marinus) in an electronic shuttlebox

Ammocoete larvae of the sea lamprey Petromyzon marinus, a member of the primitive vertebrate class Agnatha, were tested for thermoregulatory behavior in an electronic shuttlebox (ichthyotron). The final preferendum derived from pooled data for 24 individually tested ammocoetes was characterized by a mean of 13.6 ± 0.17 (s.e.m.)°C, a mode and median of 140°C, and a range of voluntarily occupied temperatures from 10–19°C over a 3-day period.     

Ultrastructure and isolation of glyoxysomes (microbodies) in zoospores of the fungusentophlyctis sp.

Summary A correlative approach, involving light and electron microscopic, cytochemical, and biochemical techniques, was used to study the structure and function of microbodies in zoospores ofEntophlyctis sp. The same population of microbodies already existing in the zoosporangium appeared to be segregated into zoospore initials during cytoplasmic cleavage. Microbodies laid at the anterior end of zoospores and were part of an organized assemblage of organelles, the microbody-lipid globule complex. In the microbody-lipid globule complex, endoplasmic reticulum occurred on the surface of the lipid globules toward the zoospore's exterior, and the microbody, subtended by mitochondria, was appressed to the opposite surface of the lipid globule. The organization of the microbody-lipid globule complex changed as the zoospore swam and encysted. As lipid globules coalesced, the microbody-lipid globule complex became disorganized. After lipid globule coalescence was completed, the microbody-lipid globule complex regained its order, and several microbodies were clustered adjacent to a single lipid globule. The microbodies persisted even in the encysted zoospore, but they were found on all sides of the lipid globule.Microbodies isolated from zoospores contained catalase as well as malate synthase and isocitrate lyase, two enzymes of the glyoxylate cycle. When zoospores encysted greater activities of these glyoxylate cycle enzymes could be detected. The presence of glyoxylate cycle enzymes and the close association between the microbody and lipid globule suggest that microbodies function as glyoxysomes in zoospores and encysted zoospores. The functional significance of the morphological organization of the microbody-lipid complex is discussed in terms of energy production and the conversion of storage lipid into structural components of the cell.     

Protoplast induction inMicrasterias andCosmarium

Summary Protoplasts of the desmidsMicrasterias angulosa, M. denticulata, M. thomasiana andCosmarium turpinii were obtained by incubating cells in Waris' liquid medium + 0.3 M mannitol + 2% Cellulysin for 1–3 hours. One osmotically fragile protoplast was formed at the isthmus from the joint contents of both semicells. The resultant protoplasts were bright green and remained so for more than 5 days in the osmotically protective medium. The protoplast yield was better than 80%. The empty cell walls were not digested by the Cellulysin or by autolytic enzymes.     

A 25,000 molecular weight protein constituent of human amyloid fibrils related to amyloid protein AA

Amyloid fibrils from a patient with diffuse amyloid disease are dissociated in 6 m guanidine hydrochloride and fractionated by gel chromatography. Two major components are separated on Sepharose 6B. Both proteins are characterized by chromatography, immunodiffusion, discontinuous gel electrophoresis, amino acid tryptic peptide mapping and amino acid sequence analysis. The smaller of the two components is typical of the known protein AA by size (8400 daltons), amino acid composition and a 30-residue N-terminal sequence. The larger of the components (25,000 daltons) undergoes electrophoresis as a single band and appears unaffected by thiol reduction. It differs from protein AA in amino acid content and by its tryptic peptide map, although it contains an N-terminal amino acid sequence identical to protein AA when carried to 20 residues. Treatment of this larger component by mild acid hydrolysis results in the release of the 8400-dalton protein AA. Fractionation after guanidine hydrochloride treatment of this particular amyloid fibril preparation is compared to the fractionation of a typical secondary amyloid preparation that contains only protein AA as the major component. The origin and relationship of the 8,400- and 25,000-dalton protein components is discussed.     

Factors affecting the yield of virus in a cloned cell line of Trichoplusia ni infected with a nuclear polyhedrosis virus

The TN-368 tissue culture line of the cabbage looper, Trichoplusia ni, has been cloned. The doubling times of three clones at 27°C were 27.6 ± 3.4 hr, 21.9 ± 1.7 hr, and 27.4 ± 5.9 hr and that of the uncloned culture was 15.8 ± 1.5 hr. Growth of cells in all cultures was arrested after infection with a nuclear polyhedrosis virus of T. ni. There was little difference in the yield of polyhedra from cultures of uncloned or cloned cells infected at a multiplicity of infection (m.o.i) = 4. Yields of polyhedra were about the same when a m.o.i. was in the range of 0.01–4.0, but the yield tripled in the range m.o.i. = 20–30. At higher multiplicities, up to m.o.i. = 500 the yield of polyhedra progressively fell. It is concluded that the observed variation in numbers of polyhedra borne by individual cells in culture is not due to genetic variability among cells, nor can it be accounted for as a consequence of differing m.o.i. by virus. It is postulated that variation in polyhedra yield among cells in culture may be due to such factors as (1) strain differences in the virus, (2) the stage in the cell cycle at which a particular cell is present when infected.     

Dental Implications of Pharmacological Management of the Alzheimer's Patient

Medications used for the management of the Alzheimer's patient are of two types: agents prescribed for treatment of cognitive disorders and agents used for symptomatic relief of mood disorders. This article reviews the mechanisms of action and side-effects of the more common of these agents. In addition, dental management of the Alzheimer's patient is discussed in relation to specific medications being taken.     

Evolution of the C4 photosynthetic pathway: events at the cellular and molecular levels

The biochemistry and leaf anatomy of plants using C₄ photosynthesis promote the concentration of atmospheric CO₂ in leaf tissue that leads to improvements in growth and yield of C₄ plants over C₃ species in hot, dry, high light, and/or saline environments. C₄ plants like maize and sugarcane are significant food, fodder, and bioenergy crops. The C₄ photosynthetic pathway is an excellent example of convergent evolution, having evolved in multiple independent lineages of land plants from ancestors employing C₃ photosynthesis. In addition to C₃ and C₄ species, some plant lineages contain closely related C₃–C₄ intermediate species that demonstrate leaf anatomical, biochemical, and physiological characteristics between those of C₃ plants and species using C₄ photosynthesis. These groups of plants have been extremely useful in dissecting the modifications to leaf anatomy and molecular biology, which led to the evolution of C₄ photosynthesis. It is now clear that great variation exists in C₄ leaf anatomy, and diverse molecular mechanisms underlie C₄ biochemistry and physiology. However, all these different paths have led to the same destination—the expression of a C₄ CO₂ concentrating mechanism. Further identification of C₄ leaf anatomical traits and molecular biological components, and understanding how they are controlled and assembled will not only allow for additional insights into evolutionary convergence, but also contribute to sustainable food and bioenergy production strategies.